Gravity Wave Excitation during the Coastal Transition of an Extreme Katabatic Flow in Antarctica

Vignon, Étienne; Picard, Ghislain; Durán‐Alarcón, Claudio; Alexander, Simon P.; Gallée, Hubert; Berne, Alexis

doi:10.1175/jas-d-19-0264.1

Cited by 21 publications

(24 citation statements)

References 69 publications

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“…As reported by Vignon et al (2020) using station measurements, there is a relatively quiescent period before the 9th of August 2017 with stable wind speed, wind direction and air temperature recorded at DDU. The situation dramatically changes on the 9th when the katabatic flow rapidly strengthens and very high wind speeds are reported at DDU in the first half of the 10th.…”

Section: Resultsmentioning

confidence: 62%

“…At 1200 hrs on the 10th, there is a sudden drop in the wind speed, following which the wind becomes gusty but on average remains slower than the previous day. Vignon et al (2020) showed that the abrupt deceleration of the katabatic flow is due to excitation of gravity waves and the enhanced friction induced. nested domains with different resolutions, particularly for wind speeds and direction.…”

Section: Resultsmentioning

confidence: 99%

“…The case study is directly inspired by the recent work of Vignon et al (2020) who present a detailed analysis on the genesis, dynamics and implications of the hydraulic jumps and the corresponding gravity waves in the region in proximity of DDU.…”

Section: Objectivesmentioning

confidence: 99%

“…As mentioned earlier, CRYOWRF is compatible with the nesting capability of WRF. Finally, unlike, Vignon et al (2020), who used standard WRF, CRYOWRF includes the blowing snow model, which allows for studying the impact of hydraulic jump formation on blowing snow dynamics and simulate the formation of the aforementioned 'snow walls' for the first time.…”

Section: Objectivesmentioning

confidence: 99%

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Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

Sharma

Gerber

Lehning

2021

Preprint

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Abstract. Accurately simulating snow-cover dynamics and the snow-atmosphere coupling is of major importance for topics as wide-ranging as water resources, natural hazards and climate change impacts with consequences for sea-level rise. We present a new modelling framework for atmospheric flow simulations for cryospheric regions called CRYOWRF. CRYOWRF couples the state-of-the-art and widely used atmospheric model WRF, with the detailed snow-cover model SNOWPACK. CRYOWRF makes it feasible to simulate dynamics of a large number of snow layers governed by grain-scale prognostic variables with online coupling to the atmosphere for multiscale simulations from the synoptic to the turbulent scales. Additionally, a new blowing snow scheme is introduced in CRYOWRF and is discussed in detail. CRYOWRF's technical design goals and model capabilities are described and performance costs are shown to compare favourably with existing land surface schemes. Three case studies showcasing envisaged use-cases for CRYOWRF for polar ice sheets and alpine snowpacks are provided to equip potential users with templates for their research. Finally, the future road-map for CRYOWRF's development and usage is discussed.

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Section: Resultsmentioning

confidence: 62%

Section: Resultsmentioning

confidence: 99%

Section: Objectivesmentioning

confidence: 99%

Section: Objectivesmentioning

confidence: 99%

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Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

Sharma

Gerber

Lehning

2021

Preprint

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“…Conversely, Dumont D'Urville is located on Petrel Island and approximately 5 km from the main ice sheet. It is subject to strong katabatic winds, which flow from the Antarctic interior, which can also generate gravity waves (Vignon et al, 2020). It is also expected, from previous studies (Moffat-Griffin et al, 2011, 2013, that those stations close to the Drake Passage will see greater levels of gravity wave activity as this is where the main gravity wave "hotspot" is located.…”

Section: Radiosonde Datamentioning

confidence: 89%

Radiosonde Observations of a Wintertime Meridional Convergence of Gravity Waves Around 60°S in the Lower Stratosphere

Moffat‐Griffin

Colwell

Hindley

et al. 2020

Geophysical Research Letters

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Satellite observations show that there is a wintertime hotspot of gravity wave activity, located mainly over the ocean, around 60°S in the stratosphere. However, the sources of the gravity waves making up this hotspot are varied and complex and remain unclear. Here we use radiosonde observations from 11 Antarctic stations and selected small islands close to 60°S to examine the horizontal directional pseudo-momentum flux and energy density distributions of upward propagating gravity waves in the lower stratosphere. This paper shows, for the first time, that short vertical wavelength gravity waves in the lower stratosphere clearly propagate meridionally toward 60°S during the winter months. This result supports previous studies that show that this belt of gravity wave activity over the ocean is contributed to by wave sources outside 60°S. Plain Language Summary Atmospheric gravity waves are buoyancy waves, where the restoring force is gravity, which can have horizontal wavelengths from a few tens to hundreds of kilometers. They can be generated by a variety of sources including wind flow over mountains and storms. Over the Drake Passage and out to the east around 60°S, a large hotspot of gravity waves has been observed in the wintertime stratosphere using satellite observations. The sources for this gravity wave hotspot are unclear as it mainly located over the open ocean. In this paper radiosonde observations are used to examine, for the first time, the directional variation in short vertical wavelength gravity waves close to 60°S in the lower stratosphere. It is found that during the winter months there is a meridional convergence of gravity waves toward 60°S, implying that the gravity wave sources of the hotspot are in fact be outside this region.

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On gravity wave parameterisation in vicinity of low‐level blocking

Geldenhuys

2022

Atmospheric Science Letters

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This note is framed as an open question to the community regarding parameterisation schemes using the blocking layer depth to reduce the orographic gravity wave drag. It is the purpose of this note to argue that the current orographic gravity wave drag parameterisation in the vicinity of blocking is inadequate. Reducing the gravity wave amplitude (and thereby reducing the gravity wave drag) by assuming an effective mountain height dependent on the blocking depth is not realistic. The arguments given here will hopefully spark a debate and new considerations, ultimately leading to improvements in current orographic gravity wave drag parameterisations. This note illustrates that low-level blocking can induce more gravity waves or gravity waves with a higher momentum flux (compared to the current parameterisation schemes). More realistic parameterisation schemes are likely to improve the models' performance. However, the fact is complex theories are needed to describe gravity wave excitation by orography so that it is difficult to represent gravity wave nature by a 'too simple' parameterisation scheme.

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Gravity Wave Excitation during the Coastal Transition of an Extreme Katabatic Flow in Antarctica

Cited by 21 publications

References 69 publications

Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

Introducing CRYOWRF v1.0: Multiscale atmospheric flow simulations with advanced snow cover modelling

Radiosonde Observations of a Wintertime Meridional Convergence of Gravity Waves Around 60°S in the Lower Stratosphere

On gravity wave parameterisation in vicinity of low‐level blocking

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